Development of embryonic stem cells expressing endogenous levels of a fluorescent protein fused to the telomere binding protein TRF1

Miller, Shelley Bonnie

11 1900

Telomeres are the repetitive DNA sequence and associated proteins found at the ends of linear chromosomes. They have a role in biological processes including meiosis and aging as well as implications in a number of genomic instability disorders and cancers. Telomeres maintain genomic stability by protecting chromosome ends from terminal fusions and misidentification as DNA damage sites. Their wide range of functions has resulted in an increased interest in developing tools to study the dynamics of telomeres in live cells. To do this, current studies use the ubiquitously expressed protein Telomere Repeat Factor 1 (TRF1) tagged with a fluorescent protein. TRF1 is a negative regulator of telomere length that binds exclusively to telomere repeats. Over-expression of the fluorescent protein fused to TRF1 has been a useful tool to track telomere movement. The foci formed by the tagged TRF1 protein accurately represent the number of telomeres expected in the cells and the localization is maintained throughout the cell cycle. A caveat with this system is that over-expression of TRF1 leads to accelerated telomere shortening, as well as replication defects that can stall telomere replication. These caveats make it difficult to draw conclusions about telomere dynamics based solely on observations of cells over-expressing fluorescently tagged TRF1. To eliminate problems associated with protein over-expression, I have tried to develop knock-in embryonic stem (ES) cells expressing fluorescently tagged TRF1 from the endogenous Trf1 promoter. To do this, I have used a recombineering technique using Bacterial Artificial Chromosomes (BACs). BAC recombineering allows for the direct knock-in of a fluorescent tag into the mouse Trf1gene locus. Genetic constructs with the correct sequence inserts have been obtained and have been used for transfection of ES cells. While no correctly targeted ES cells have been identified so far, the expectation is that ES cell lines with correctly targeted fluorescently tagged TRF1 will be obtained in the near future. Such lines will be used to study telomere dynamics in ES cells, differentiated cells generated from ES cells, as well as to generate mice.

Telomeres

TRF1

Embryonic stem cells

Recombineering

Mechanisms of c-Myc dependent genomic instability

Louis, Sherif

03 September 2009

Cancer is a disease that involves genomic instability, to which c-Myc contributes during its initiation and progression. Over 70% of all human cancers show deregulated levels of c-Myc protein. The term genomic instability refers to genetic and/or epigenetic changes that alter the normal organization and function of genes and chromosomes. Genomic instability is a hallmark of cancer and often is associated with cancer. Deregulated c-Myc expression generates genomic instability by initiating intra- and extrachromosomally locus-specific gene amplification, gene rearrangements and karyotypic instability that includes translocations, fusions, insertions and deletions. Out of the several outlined pathways by which deregulated levels of c-Myc can lead to genomic instability, the work described in this thesis focuses on three with direct relevance to tumorigenesis; gene amplification (increase in gene copy number), remodeling of the chromosomal and telomeric structures in the interphase nucleus and comparing the effect of Myc to that of Epstein Bar virus (EBV) infection in remodeling the nuclear structure that may lead to genomic instability.

Genomic instability

Gene amplification

Oncoproteins

Telomeres

Mechanisms of c-Myc dependent genomic instability

Louis, Sherif

03 September 2009

Cancer is a disease that involves genomic instability, to which c-Myc contributes during its initiation and progression. Over 70% of all human cancers show deregulated levels of c-Myc protein. The term genomic instability refers to genetic and/or epigenetic changes that alter the normal organization and function of genes and chromosomes. Genomic instability is a hallmark of cancer and often is associated with cancer. Deregulated c-Myc expression generates genomic instability by initiating intra- and extrachromosomally locus-specific gene amplification, gene rearrangements and karyotypic instability that includes translocations, fusions, insertions and deletions. Out of the several outlined pathways by which deregulated levels of c-Myc can lead to genomic instability, the work described in this thesis focuses on three with direct relevance to tumorigenesis; gene amplification (increase in gene copy number), remodeling of the chromosomal and telomeric structures in the interphase nucleus and comparing the effect of Myc to that of Epstein Bar virus (EBV) infection in remodeling the nuclear structure that may lead to genomic instability.

Genomic instability

Gene amplification

Oncoproteins

Telomeres

Development of embryonic stem cells expressing endogenous levels of a fluorescent protein fused to the telomere binding protein TRF1

Miller, Shelley Bonnie

11 1900

Telomeres are the repetitive DNA sequence and associated proteins found at the ends of linear chromosomes. They have a role in biological processes including meiosis and aging as well as implications in a number of genomic instability disorders and cancers. Telomeres maintain genomic stability by protecting chromosome ends from terminal fusions and misidentification as DNA damage sites. Their wide range of functions has resulted in an increased interest in developing tools to study the dynamics of telomeres in live cells. To do this, current studies use the ubiquitously expressed protein Telomere Repeat Factor 1 (TRF1) tagged with a fluorescent protein. TRF1 is a negative regulator of telomere length that binds exclusively to telomere repeats. Over-expression of the fluorescent protein fused to TRF1 has been a useful tool to track telomere movement. The foci formed by the tagged TRF1 protein accurately represent the number of telomeres expected in the cells and the localization is maintained throughout the cell cycle. A caveat with this system is that over-expression of TRF1 leads to accelerated telomere shortening, as well as replication defects that can stall telomere replication. These caveats make it difficult to draw conclusions about telomere dynamics based solely on observations of cells over-expressing fluorescently tagged TRF1. To eliminate problems associated with protein over-expression, I have tried to develop knock-in embryonic stem (ES) cells expressing fluorescently tagged TRF1 from the endogenous Trf1 promoter. To do this, I have used a recombineering technique using Bacterial Artificial Chromosomes (BACs). BAC recombineering allows for the direct knock-in of a fluorescent tag into the mouse Trf1gene locus. Genetic constructs with the correct sequence inserts have been obtained and have been used for transfection of ES cells. While no correctly targeted ES cells have been identified so far, the expectation is that ES cell lines with correctly targeted fluorescently tagged TRF1 will be obtained in the near future. Such lines will be used to study telomere dynamics in ES cells, differentiated cells generated from ES cells, as well as to generate mice.

Telomeres

TRF1

Embryonic stem cells

Recombineering

The role of Alternative Lengthening of Telomeres in human cancer

Henson, Jeremy D

January 2006

Doctor of Philosophy / Activation of a telomere maintenance mechanism is a vital step in the development of most cancers and provides a target for the selective killing of cancer cells. Cancers can use either telomerase or Alternative Lengthening of Telomeres (ALT) to maintain their telomeres and inhibition of either telomere maintenance mechanism can cause cancer cells to undergo senescence or apoptosis. Although telomerase inhibitors are undergoing clinical trials, on commencing this study very little was known about the role of ALT in cancer, what proteins were involved in its mechanism and regulation and how it could be targeted clinically. The primary aim of this thesis was to develop an assay for ALT suitable for examining archived tumour specimens and to begin using it to examine the prevalence and clinical significance of ALT in cancer. This assay and gene expression analysis was also used to identify genes that are involved in or associated with the activation of the ALT mechanism, to contribute towards the overall goal of an ALT cancer therapy. The ALT mechanism involves recombination mediated replication and ALT cells have a marked increase in a range of recombinational events specifically at their telomeres. Presumably, as a consequence of this the telomere lengths of ALT cells are very heterogeneous and on average long. This can be detected by terminal restriction fragment (TRF) Southern analysis, which has been used previously as the definitive test for ALT activity. However, TRF analysis requires intact genomic DNA and is unsuitable for tumour specimens which are commonly archived by paraffin embedding. Another hallmark of ALT is ALT-associated PML bodies (APBs) which are the subset of PML bodies that contain telomeric DNA. Work done in this study to consolidate APBs as a hallmark of ALT, combined with published data, showed 29/31 ALT[+], 3/31 telomerase[+] and 0/10 mortal cell lines/strains are APB[+]. The three APB[+]/telomerase[+] cell lines identified here had an order of magnitude lower frequency of APB[+] nuclei than the ALT[+] cell lines. APBs may be functionally linked to the ALT mechanism and contain the recombination proteins that are thought to be involved in the ALT mechanism. This study, in collaboration with Dr W-Q Jiang, strengthened this functional link by demonstrating that loss of ALT activity (as determined by TRF analysis) coincided with the disruption of APBs. The detection of APBs was developed into a robust assay for ALT in archived tumour specimens using a technique of combined immunofluorescence and telomere fluorescence in situ hybridisation. It was demonstrated that the APB assay concurred exactly with the standard assay for ALT (TRF analysis) in 60 tumours for which TRF analysis gave unequivocal results. The APB assay may be a more appropriate technique in the case of tumour specimen heterogeneity, which may explain why the APB assay was able to give definitive results when TRF analysis was equivocal. We demonstrated that intratumoral heterogeneity for ALT does exist and this could explain why about 3% of tumours in this study were APB[+] but with more than a ten-fold reduction in the frequency of APB[+] nuclei. This study also made the novel discovery of single stranded C-rich telomeric DNA inside APBs which potentially could be used to make the APB assay more suitable for routine pathology laboratory use. The APB assay was used to show that ALT is a significant concern for oncology. ALT was utilised in approximately one quarter of glioblastoma multiforme (GBM), one third of soft tissue sarcomas (STS) including three quarters of malignant fibrous histiocytomas (MFH), half of osteosarcomas and one tenth of non-small cell lung carcinomas (NSCLC). Furthermore, the patients with these ALT[+] tumours had poor survival; median survivals were 2 years for ALT[+] GBM, 4 years for ALT[+] STS including 3.5 years for ALT[+] MFH and 5 years for ALT[+] osteosarcoma. ALT[+] STS and osteosarcomas were also just as aggressive as their ALT[-] counterparts in terms of grade and patient outcome. ALT status was not found to be associated with response to chemotherapy in osteosarcomas or survival in STS. ALT was however, less prevalent in metastatic STS. The APB assay was a prognostic indicator for GBM and was correlated with three fold increased median survival in GBM (although this survival was still poor). ALT was more common in lower grade astrocytomas (88% ALT[+]) than GBM (24% ALT[+]) and ALT[+] GBM had an identical median age at diagnosis to that reported for secondary GBM. It is discussed that these data indicate that ALT was indirectly associated with secondary GBM and is possibly an early event in its progression from lower grade astrocytoma. This is relevant because secondary GBM have distinct genetic alterations that may facilitate activation of the ALT mechanism. Putative repressors of ALT could explain why this study found that ALT varied among the different STS subtypes. ALT was common in MFH (77%), leiomyosarcoma (62%) and liposarcoma (33%) but rare in rhabdomyosarcoma (6%) and synovial sarcoma (9%). ALT was not found in colorectal carcinoma (0/31) or thyroid papillary carcinoma (0/17) which have a high prevalence of telomerase activity and a reduced need for a telomere maintenance mechanism (low cell turnover), respectively. A yeast model of ALT predicts that one of the five human RecQ helicases may be required for ALT. Using the APB assay to test for the presence of ALT in tumours from patients with known mutations in either WRN or RECQL4 it was demonstrated that neither of these RecQ helicases is essential for ALT. Although p53 and mismatch repair (MMR) proteins have been suggested to be possible repressors of ALT, there was no apparent increase in the frequency of ALT in tumours from patients with a germline mutation in p53 codon 273 or in colorectal carcinomas that had microsatellite instability and thus MMR deficiency. Also contrary to being a repressor of ALT but consistent with its ability to interact with a protein involved in the ALT mechanism, the MMR protein MLH1, was demonstrated to be present in the APBs of an ALT[+] cell line. To further test for genes that may be involved in the ALT mechanism or associated with its activation, RNA microarray was used to compare the gene expression of 12 ALT[+] with 12 matched telomerase[+] cell lines; 240 genes were identified that were significantly differentially expressed (p<0.005) between the ALT[+] and telomerase[+] cell lines. Only DRG2 and SFNX4 were significantly differentially expressed after adjusting for the estimated false positive rate. Overall, DRG2, MGMT and SATB1 were identified as most likely to be relevant to the ALT[+] tumours and Western analysis indicated that DRG2 and MGMT levels were down-regulated after activation of ALT and up-regulated after activation of telomerase, whereas SATB1 protein levels appeared to be up-regulated after immortalisation but to a higher degree with activation of ALT compared to telomerase. Since lack of MGMT is known to be a determinant of temozolomide sensitivity in GBM, the possibility that ALT and the APB assay could be used to predict temozolomide sensitivity is discussed. The microarray data was consistent with MGMT expression being suppressed by EGF (p < 0.05), indicating that caution may be needed with combining EGFR inhibitors with temozolomide in ALT cancers. One ALT[+] cell line which did not express MGMT had TTAA sequence in its telomeres. This could possibly have resulted from mutations due to lack of MGMT expression and a possible role for MGMT in the ALT mechanism is discussed. Further analysis of the microarray data identified two groups of co-regulated genes (p < 5x10-5): CEBPA, TACC2, SFXN4, HNRPK and MGMT, and SIGIRR, LEF1, NSBP1 and SATB1. Two thirds of differentially expressed genes were down-regulated in ALT. Chromosomes 10 and 15 had a bias towards genes with lower expression in ALT while chromosomes 1, 4, 14 and X had a bias towards genes with higher expression levels in ALT. This work has developed a robust assay for ALT in tumour specimens which was then used to show the significance of ALT in sarcomas, astrocytomas and NSCLC. It has also identified genes that could possibly be molecular targets for the treatment of ALT[+] cancers.

Cancer

Telomere

Identificação e caracterização de proteinas que se associam 'in vitro' a fita telomerica rica em G de 'Leishmania (Leishmania) amazonensis' / Identification and characterization of proteins that associate in vitro with the Leishmania (Leishmania) amazonensis G-rich telomeric strand

Fernandez, Maribel Fernandez

15 October 2004

Orientador: Maria Isabel Nogueira Cano / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-06T16:01:48Z (GMT). No. of bitstreams: 1 Fernandez_MaribelFernandez_D.pdf: 2528780 bytes, checksum: f2c8b7a6e63a773b6160e0d483156743 (MD5) Previous issue date: 2004 / Resumo: Os terminais dos cromossomos de Leishmania (Leishmania) amazonensis contêm repetições teloméricas mantidas pela enzima telomerase da seqüência 5'-TTAGGG-3', a qual é conservada também em outros tripanosomatídeos e outros eucariotos. Utilizando-se frações protéicas purificadas a partir de extratos S100 e nuclear, foi possível se detectar atividade de telomerase e três complexos proteína-DNA que se associam in vitro com seqüências teloméricas ricas em G do parasita. A atividade de telomerase de L. (L.) amazonensis foi detectada por ensaio TRAP ("Telomeric Repeat Amplification Protocol") e apresenta características comuns às telomerases já descritas em outros tripanosomatídeos. Os complexos proteína-DNA foram identificados por EMSA ("Electrophoretic Mobility Shift Assays") e ensaios de "UV cross-linking" e denominados LaGT1-3 (Leishmania amazonensis G-strand telomeric protein 1-3). Eles não são formados: i) com DNA telomérico na forma de dupla fita e com fita rica em C, ii) em experimentos de competição específica usando oligonucleotídeos de seqüências de DNA telomérico, ou iii) após o tratamento enzimático com proteinase K. LaGT1 foi o complexo mais específico, o qual é formado com todas as seqüências de DNA telomérico (Tel1-6, Tel30 e Tel36) e não se associa à seqüência telomérica de Tetrahymena. As proteínas que formam os três complexos associam-se com uma seqüência de RNA telomérico rica em G e um complexo similar a LaGT1 é formado com DNA telomérico na forma de dupla fita contendo uma projeção 3' simples fita terminal. A estimativa das constantes de dissociação (Kd) do complexo LaGT1 associado a seqüência telomérica na forma de DNA e dos complexos LaGT2 e LaGT3 associados a seqüências teloméricas na forma de DNA ou RNA, demonstra que estes se encontram na ordem de nM, característica comum a proteínas que ligam DNA na forma de simples fita. Os componentes protéicos dos complexos LaGT2 e LaGT3 foram purificados por cromatografia de afinidade e identificados após renaturação, como bandas de ~35 kDa e ~52 kDa, respectivamente. O componente protéico de < 15 kDa de LaGT1 foi purificado em gel como um complexo irradiado com luz UV de ~18-20 kDa. Os componentes protéicos de LaGT2 e LaGT3 e o complexo irradiado LaGT1 foram digeridos em gel com tripsina e os peptídeos trípticos resultantes foram analisados por espectrometria de massa utilizando-se as técnicas: "Matrix-Assisted Laser Desorption/Ionization-Time of Flight" (MALDI-TOF) e "Liquid Chromatography Electrospray Ionization tandem Mass Spectrometry" (LC/ESIMS/MS), a análise dos espectros demonstrou que o componente protéico de ~35 kDa de LaGT2 é homólogo da proteína Rbp38 de Leishmania spp. enquanto, o componente protéico de ~52 kDa de LaGT3 é similar à subunidade 1 da proteína de replicação A (Rpa-1) de Leishmania spp. O componente protéico de < 15 kDa de LaGT1 provavelmente uma proteína de L. (L.) amazonensis que ainda não foi identificada. A identificação das proteínas por espectrometria de massa, possibilitou a clonagem dos genes que codificam às mesmas. Neste trabalho apresentamos a caracterização parcial do gene que codifica o componente protéico do complexo LaGT3: subunidade 1 da proteína de replicação A de L. (L.) amazonensis (LaRpa-1). A análise da sua organização genômica demonstrou que o mesmo encontra-se provavelmente em baixo número de cópias ou em cópia única no genoma do parasita e que ele se localiza em uma banda cromossômica de ~0,8 Mb. Foi realizada também a análise conformacional parcial da interação entre a proteína nativa renaturada LaRpa-1 e o DNA telomérico rico em G de L. (L.) amazonensis (oligonucleotídeo Tel6) por espectroscopia de fluorescência mostrando-se um aumento da intensidade da fluorescência quando ocorre essa interação / Abstract: The chromosomal ends of Leishmania (Leishmania) amazonensis contain conserved 5'- TTAGGG-3' telomeric repeats, that are maintained by telomerase. Using Telomeric Repeat Amplification Protocol (TR AP) we detected telomerase activity in protein fractions purified from S100 and nuclear extracts. Protein complexes that associate in vitro with telomeric DNA sequences, LaGT1-3 (Leishmania amazonensis G-strand telomeric protein), were identified and characterized by electrophoretic mobility shift assays (EMSA) and UV cross-linking using protein fractions purified from S100 and nuclear extracts. The three complexes did not form i) with double strand DNA (dsDNA) and the C-rich telomeric strand, ii) in competition assays using specific telomeric DNA oligonucleotides, or iii) after pre-treatment with proteinase K. LaGT1 was the most specific, it is formed with all DNA telomeric sequences (Tel1-6, Tel30 and Tel36) and did not bind a Tetrahymena telomeric sequence. All three LaGTs associated with an RNA sequence cognate to the telomeric G-rich strand and a complex similar to LaGT1 is formed with a dsDNA bearing a 3' G-overhang tail. The dissociation constants (Kd) for LaGT1 complexed with telomeric DNA sequence, and for LaGT2-3 complexed with telomeric DNA and RNA sequences were in the nM range. The protein components of LaGT2 and LaGT3 were purified by affinity chromatography and identified, after renaturation, as ~35 kDa and ~52 kDa bands, respectively. The < 15 kDa protein component of LaGT1 was gel-purified as a UV crosslinked complex of ~18-20 kDa. LaGT2 and LaGT3 protein bands and the irradiated LaGT1 complex were digested by trypsin and the resulting peptides were analysed by mass espectrometry techniques: Matrix-Assisted Laser Desorption/Ionization-Time of Flight (MALDI-TOF) and by Liquid Chromatography Electrospray Ionization tandem Mass Spectrometry (LC/ESI-MS/MS). The fingerprint analysis showed that the ~35 kDa protein component of LaGT2 was homologous to the Leishmania spp. Rbp38 protein, whereas the ~52 kDa component of LaGT3 was similar to the putative subunit 1 of replication protein A of Leishmania spp. and the < 15 kDa protein component of LaGT1 was probably a novel Leishmania protein. The gene encoding the protein-forming complexe LaGT3 (LaRpa-1) were cloning and parcially caracterized, the genomic organization analysis of LaRPA-1 gene showed that it is present probably in low copy number or a single copy and was mapped on a chromosome of ~0,8 Mb. The partial conformational analysis of the interaction between nativeLaRpa-1 and the telomeric G-rich DNA (Tel6) was performed using fluorescence spectroscopy, this analysis showed an increase of the fluorescence when the interaction occurs / Doutorado / Genetica de Microorganismos / Doutor em Genetica e Biologia Molecular

Telômeros

Leishmania amazonensis

Cromatina

Telomeres

Chromatin

Development of embryonic stem cells expressing endogenous levels of a fluorescent protein fused to the telomere binding protein TRF1

Miller, Shelley Bonnie

11 1900

Telomeres are the repetitive DNA sequence and associated proteins found at the ends of linear chromosomes. They have a role in biological processes including meiosis and aging as well as implications in a number of genomic instability disorders and cancers. Telomeres maintain genomic stability by protecting chromosome ends from terminal fusions and misidentification as DNA damage sites. Their wide range of functions has resulted in an increased interest in developing tools to study the dynamics of telomeres in live cells. To do this, current studies use the ubiquitously expressed protein Telomere Repeat Factor 1 (TRF1) tagged with a fluorescent protein. TRF1 is a negative regulator of telomere length that binds exclusively to telomere repeats. Over-expression of the fluorescent protein fused to TRF1 has been a useful tool to track telomere movement. The foci formed by the tagged TRF1 protein accurately represent the number of telomeres expected in the cells and the localization is maintained throughout the cell cycle. A caveat with this system is that over-expression of TRF1 leads to accelerated telomere shortening, as well as replication defects that can stall telomere replication. These caveats make it difficult to draw conclusions about telomere dynamics based solely on observations of cells over-expressing fluorescently tagged TRF1. To eliminate problems associated with protein over-expression, I have tried to develop knock-in embryonic stem (ES) cells expressing fluorescently tagged TRF1 from the endogenous Trf1 promoter. To do this, I have used a recombineering technique using Bacterial Artificial Chromosomes (BACs). BAC recombineering allows for the direct knock-in of a fluorescent tag into the mouse Trf1gene locus. Genetic constructs with the correct sequence inserts have been obtained and have been used for transfection of ES cells. While no correctly targeted ES cells have been identified so far, the expectation is that ES cell lines with correctly targeted fluorescently tagged TRF1 will be obtained in the near future. Such lines will be used to study telomere dynamics in ES cells, differentiated cells generated from ES cells, as well as to generate mice. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Telomeres

TRF1

Embryonic stem cells

Recombineering

Drivers of melanoma susceptibility

Robles Espinoza, Carla Daniela

January 2015

Cutaneous melanoma is a cancer of melanocytes, the pigment-producing cells in our skin. It is one of the most aggressive human malignancies, constituting only about 2% of all dermatological cancers but being responsible for over 75% of all deaths from skin cancer. It has recently become a major public health problem, as it is now the fifth most common cancer in the United Kingdom after its incidence more than quadrupled in the last three decades. For these reasons, understanding the biological processes that are involved in its development is of great importance for devising novel treatments and for the management of patients in the clinic. The study of the genetic factors that influence melanoma risk can uncover mechanisms that are relevant in the transition from a benign melanocyte to a malignant melanoma. Approximately 10% of all melanoma cases are familial, and about half of these familial cases can be explained by pathogenetic variants in genes such as cyclin-dependent kinase inhibitor 2A (CDKN2A), cyclin-dependent kinase 4 (CDK4), breast cancer 2 (BRCA2), BRCA1-associated protein-1 (BAP1) and in the promoter of the telomerase reverse transcriptase (TERT). However, about 50% of all familial melanoma cannot be explained by mutations in known genes. In this dissertation, I detail the methodology I followed in an effort to uncover additional high-penetrance melanoma susceptibility genes. I analysed exome and genome sequence data from a total of 184 individuals that belong to 105 melanoma-prone families from the United Kingdom, The Netherlands and Australia that did not have any pathogenetic variants in known susceptibility genes. I applied different gene prioritisation strategies and developed novel software tools in order to devise a list of plausible melanoma susceptibility candidate genes; these analyses suggested that genes regulating telomere function could be influencing melanoma risk. After performing functional experimental analyses, our research team was able to determine that carriers of rare variants in the protection of telomeres (POT1) gene, a member of the shelterin complex that safeguards telomere integrity, are at high risk for developing melanoma. We successfully described the mechanism by which this happens, showing that the variants identified either disrupt POT1 mRNA splicing or abolish the ability of POT1 to bind to telomeres, and lead to increased telomere length in carriers when compared to melanoma cases with wild-type POT1. The main finding of the work described in this dissertation is the identification of telomere dysfunction as an important contributor to the risk of developing melanoma, and possibly other cancers. Our analyses suggest that POT1 is the second most commonly mutated high-penetrance melanoma susceptibility gene reported thus far, and moreover, that rare variants in this gene constitute the first hereditary mechanism for telomere lengthening in humans.

616.99

Effects of polychlorinated biphenyls (PCBs) on telomere maintenance in hematopoietic stem cells and progenitor cells

Xin, Xing

01 December 2015

Polychlorinated biphenyls (PCBs) are synthetic persistent organic compounds that are known to be carcinogenic to humans. Changes in telomerase activity and telomere length are hallmarks of aging and carcinogenesis. Retention of telomerase activity and long telomeres are key characteristics of stem cells and progenitor cells. I hypothesize that PCBs modulate telomerase activity and telomeres of hematopoietic stem cells and progenitor cells via interference of gene regulation and potentially disrupt cell differentiation. To investigate this possibility, I used progenitor-like cells, human promyelocytic leukemia cells (HL-60), and stem cells from rat bone marrow. I show that PCB126 and PCB153 display toxic effects on telomerase activity, telomere length and their related gene expression in progenitor-like HL-60 cells, but they did not exert much effect on differentiation. Further, an in vivo/in vitro study using rat bone marrow cells shows that PCB126-induced hematotoxicity, evidenced by reduction in telomerase activity and TERT gene expression, an increase of the differentiation and a change in the differentiation direction towards granulocytes, which indicate an effect on stem cell function. I also show that the most potent dioxin-like congener, PCB126, regulates hTERT gene expression by activation of the AhR pathway. Both AhR and ARNT work together as a repressor of hTERT transcription. This research improves our understanding of mechanisms of PCB126 and PCB153 toxicity on hematopoietic stem cells and progenitor cells, which will ultimately have significant implications for human health.

publicabstract

PCBs

Stem cells

Telomerase

Telomeres

Toxicology

Defining mechanisms that regulate the alternative lengthening of telomeres

Mason-Osann, Emily

30 January 2020

Telomeres are repetitive DNA sequences found at the ends of eukaryotic chromosomes that help maintain genome stability. Telomeres shorten every time a cell divides, eventually inducing replicative senescence. To gain replicative immortality cancer cells establish mechanisms to maintain telomere length over many cell divisions. Around 10% of cancers do this using a recombination-based pathway called the Alternative Lengthening of Telomeres (ALT). ALT resembles a specific type of homology-directed repair called break-induced replication (BIR). Through this body of work, we aimed to better understand both the genetics underlying ALT positive cancers and the mechanistic basis of ALT. ALT positive cancers frequently carry loss of function mutations in the genes for ATRX/DAXX, which function to regulate heterochromatin. Recently, we identified a novel chromosomal fusion event in ALT positive osteosarcoma causing defects in DAXX function. Additionally, we identified several osteosarcoma tumors with wild-type ATRX/DAXX that had abnormalities in SLX4IP or SMARCAL1, proteins recently shown to regulate the ALT pathway. These data suggest that a more thorough understanding of the ALT mechanism may reveal additional factors that are defective in ALT positive tumors. Building on this, we aimed to further define the mechanism of ALT by investigating the DNA translocase RAD54 in the ALT pathway. During BIR, a broken DNA strand invades a homologous template, forming a structure called a displacement loop (D-loop) where a strand of template DNA is displaced to allow base pairing between the broken DNA strand and the homologous template. The D-loop recruits DNA polymerases, leading to extension and repair of the broken DNA strand. RAD54 is known to regulate both the formation and resolution of D-loops. In this work, we found that RAD54 promotes elongation at ALT telomeres by mediating branch migration and dissolution of the D-loop. D-loops formed at ALT telomeres must be resolved before mitosis to prevent the formation of ultra-fine anaphase bridges. These data demonstrate that by mediating D-loop migration RAD54 plays an important role in both promoting telomere elongation and maintaining genome stability in ALT cells. Together this body of work represents advances in defining both the genetic and mechanistic basis of ALT. / 2021-01-30T00:00:00Z

Pharmacology

Alternative lengthening of telomeres

Cancer

RAD54

Telomere